Near Degeneracy Effects on the Low-Lying Spectrum of the Iron Atom

J. Phys. Chem. A 2010, 114, 1953–1956

1953

Near Degeneracy Effects on the Low-Lying Spectrum of the Iron Atom E. Buendı´a,† F. J. Ga´lvez,† P. Maldonado,‡ and A. Sarsa*,‡ Departamento de Fı´sica Ato´mica, Molecular y Nuclear, UniVersidad de Granada, E-18071 Granada, Spain, and Departamento de Fı´sica, Campus de Rabanales, Edif. C2 UniVersidad de Co´rdoba, E-14071 Co´rdoba, Spain ReceiVed: October 6, 2009; ReVised Manuscript ReceiVed: NoVember 25, 2009

The ground state and the LS terms coming from the ground-state configuration, [Ar]-3d64s2, of the iron atom are studied by carrying out an all electron Variational Monte Carlo calculation. Explicitly correlated trial functions including near degeneracy effects are used. The effect of electronic correlations and the importance of near degeneracy effects are systematically analyzed for the states here considered and compared with the experimental values. Correlations are important to reproduce, even qualitatively, the low-lying spectrum of this atom. A significant quantitative improvement when comparing with the experimental values is achieved when near degeneracy is considered along with dynamic correlations in the variational trial wave function. Finally, the effect of relativity on the results here reported is discussed. Introduction The [Ar]-3d64s2 and [Ar]-3d74s configurations play a very important role in the low-energy spectrum of the iron atom.1 The 5D ground state arises from the 3d64s2 configuration, whereas the first excited states, 5F, 3F, and 5P arise from the 3d74s configuration. (The core [Ar] will be omitted in the notation from now on.) The subsequent levels coming from these configurations present a mixed order, with terms arising from either of the two configurations. From a theoretical point of view, noncorrelated calculations give rise to excitation energies of the first excited states that are overestimated as compared with experimental values.2,3 Electronic correlations play a very important role for the states arising from these configuration and, in general, for atoms with incomplete 3d and 4s subshells; see, for example, refs 4-7 and references therein. Therefore, large basis sets and very high levels of electron correlation are necessary to reproduce the relative ordering of the states.8 Explicitly correlated wave functions have shown to be a very convenient ansatz for describing electronic correlations in atomic systems.9 These wave functions consist of a correlation Jastrow factor, F, multiplied by a model function, Φ. A number of free parameters to be optimized in a variational Monte Carlo (VMC) calculation are included in the trial wave function. Usually, a Jastrow factor including electron-electron and electron-nucleus distances is employed.10 This function is completely symmetric with respect to the electron coordinates. The model function is usually taken as a linear combination of Slater determinants and accounts for both the antisymmetry of the total wave function and the angular momentum of the state. Single configuration model wave functions along with an energy optimized Jastrow factor have been shown to provide accurate VMC energies for atoms and single ionized cations11-13 with 3 e Z e 54. In a previous work,3 a VMC study of the ground state, 3d64s2-5D, and of the low-lying excited states arising from the * To whom correspondence should be addressed. E-mail: fa1sarua@ uco.es. † Universidad de Granada ‡ Universidad de Co´rdoba

configurations 3d64s2 and 3d74s was carried out by using a single configuration explicitly correlated trial wave function. Whereas, in general, a good description of the states under study was achieved, a different performance for the states arising from the two electronic configurations was observed. More correlation energy was recovered for the terms coming from the 3d74s configuration than for the terms from the 3d64s2 configuration. As a consequence, the excitation energy of the terms from the 3d74s configuration is underestimated by 0.03 to 0.04 hartree (i.e., between 0.8 and 1 eV) for all of the states there studied. This leads to the fact that, for example, the lowest energy term coming from the 3d74s configuration presents a VMC energy that coincides, within the statistical error, with that obtained for the ground state, whereas the experimental excitation energy is 0.032 hartree.1 To obtain a more realistic description of the levels of this atom, not only quantitatively but also qualitatively, nondynamic correlations need to be included within this scheme. There are atomic states for which two or more electronic configurations present a significant weight. This kind of correlations is harder to account for by means of a Jastrow factor. States displaying this feature require a multiconfiguration description to achieve the same degree of accuracy as that obtained for others with a stronger monoconfigurational character; see, for example, ref 12 and references therein. This is the case of the near degeneracy effect that appears in the states from the 3d64s2 configuration. A more reliable description of these states can be obtained if the 3d64p2 configuration is included in the trial wave function. In this article, we study the near degeneracy effects in the low-energy spectrum of the iron atom by using the VMC method. The states studied are the ground state as well as the lowest energy LS terms coming from the 3d64s2 configuration: 1 5D, 1 3P, 1 3H, 1 3F, 1 3G, 1 1I, 1 3D, 1 1G, 1 1D, 1 1S, and 1 1 F. As we shall see, the ground-state energy is lowered in such a way that the description of the excitation energy of the states from the 3d74s configuration is improved. Atomic units are used throughout this work. Wave Function The correlated trial wave function, Ψ, used in this work is the product of a symmetric correlation factor, F, which includes

10.1021/jp909560b  2010 American Chemical Society Published on Web 01/07/2010

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J. Phys. Chem. A, Vol. 114, No. 4, 2010

Buendı´a et al.

TABLE 1: Total Energy in Atomic Units for the Different Terms of the Ground-State Configuration 3d64s2 Calculated from a Trial Wave Function Including near Degeneracy Effects with a Jastrow Factor, EJ-MC(2), and without Correlation Factor, EMC(2)a SC

MC2

J-SC

J-MC2

term

E

Eexc

E

Eexc

E

Eexc

E

Eexc

exptl

5

-1262.43632 -1262.37090 -1262.34375 -1262.29964 -1262.32659 -1262.33781 -1262.32314 -1262.29345 -1262.27221 -1262.31137 -1262.26936 -1262.27927 -1262.26960 -1262.26143 -1262.25538 -1262.24719 -1262.25538 -1262.28859 -1262.27470 -1262.28072 -1262.24122 -1262.19790 -1262.25473 -1262.20973

0.0 0.65 0.092 0.137 0.110 0.098 0.113 0.143 0.164 0.125 0.168 0.157 0.167 0.175 0.181 0.189 0.181 0.148 0.162 0.156 0.195 0.240 0.182 0.227

-1262.46676

0.0 0.96 0.123 0.167 0.110 0.099 0.114 0.173 0.194 0.126 0.198 0.187 0.197 0.205 0.211 0.219 0.211 0.148 0.163 0.156 0.196 0.270 0.182 0.227

-1263.3757(19) -1263.3771(17) -1263.3590(28) -1263.3205(37) -1263.2682(45) -1263.2826(43) -1263.2673(35) -1263.3157(38) -1263.3149(32) -1263.2512(35) -1263.2924(32) -1263.2982(46) -1263.2931(33) -1263.2787(37) -1263.2793(34) -1263.2785(31) -1263.2838(33) -1263.2373(32) -1263.2304(31) -1263.2303(38) -1263.1979(48) -1263.2216(28) -1263.2032(42) -1263.1607(42)

0.0 -0.001(3) 0.017(3) 0.055(4) 0.107(5) 0.093(5) 0.108(4) 0.060(4) 0.061(4) 0.124(4) 0.080(4) 0.077(4) 0.083(4) 0.097(4) 0.096(4) 0.097(4) 0.092(4) 0.138(4) 0.145(4) 0.136(4) 0.178(5) 0.154(4) 0.173(4) 0.215(4)

-1263.4031(18)

0.0 0.026(3) 0.044(3) 0.082(4) 0.099(4) 0.084(3) 0.088(4) 0.087(4) 0.088(4) 0.110(4) 0.107(4) 0.105(5) 0.110(4) 0.124(4) 0.123(4) 0.124(4) 0.119(4) 0.136(4) 0.144(4) 0.136(4) 0.162(4) 0.181(3) 0.162(4) 0.194(4)

0.0 0.032 0.055 0.080 0.084 0.089 0.094 0.099 0.104 0.108 0.111 0.112 0.119 0.119 0.125 0.130 0.131 0.134 0.135 0.136 0.158 0.168

1 1 1 1 1 1 1 1 1 1 2 1 1 1 1 1 1 1 1 1 1 2 1 1

D F 3 F 5 P 3 P 3 H 3 F 3 G 3 P 3 G 3 P 1 G 3 H 3 D 1 P 1 D 1 H 1 I 3 D 1 G 1 D 3 F 1 S 1 F 5

-1262.35624 -1262.36726 -1262.35280 -1262.34116

-1262.31823 -1262.30409 -1262.31026 -1262.27071 -1262.28432 -1262.23953

-1263.3040(35) -1263.3187(26) -1263.3151(33) -1263.2926(33)

-1263.2672(38) -1263.2588(38) -1263.2673(31) -1263.2412(40) -1263.2411(34) -1263.2087(38)

a Single configuration energies, EJ-SC and ESC, for those states and for the terms arising from the 3d74s taken from ref 3 are also shown. In parentheses, we show the error in the last Figure.

the dynamic correlation among the electrons, times a model wave function, Φ, that provides the correct properties of the exact wave function such as the spin and the angular momentum of the atom and is antisymmetric in the electronic coordinates

Ψ ) FΦ

(1)

For the correlation factor, we use the form of Boys and Handy14 with the prescription proposed by Schmidt and Moskowitz.10

F ) exp

∑ Uij

(2)

i